M. Tanida, M. Okabe, K. Tagai, and K. Sakatani

Chapter 29 Evaluation of Pleasure-Displeasure Induced by Use of Lipsticks with Near-Infrared Spectroscopy (NIRS): Usefulness of 2-Channel NIRS in Neuromarketing M. Tanida, M. Okabe, K. Tagai, and K. Sakatani Abstract In order to examine whether near-infrared spectroscopy (NIRS) would be a useful neuromarketing tool, we employed NIRS to evaluate the difference of pleasure-displeasure in women, induced by the use of different types of lipsticks. The subjects used lipsticks A and B; A is softer than B. Concentration changes of oxy-hb were measured in the bilateral prefrontal cortex (PFC) during use of lipsticks A and B. We evaluated the right and left dominancy of PFC activity by calculating the Laterality Index (LI) (LI = leftδoxy-hb - rightδoxy-hb); positive LI indicates leftdominant activity while negative LI indicate right-dominant activity. We found a significant interaction between the use of lipsticks A and B, using a two- way factorial analysis of variance [F(1,13) = 9.63, p < 0.01]; Δoxy-Hb in the left PFC was larger than that in the right PFC during the use of lipstick A, while Δoxy-Hb in the right PFC tended to be larger than that in the left PFC during the use of lipstick B (p < 0.1). The LI of lipstick A was larger than that of lipstick B (paired T-test, p = 0.0083). We suggest that lipstick A caused a more positive emotional response than lipstick B, since greater left than right frontal cortical activity is associated with positive affect. These results suggest that 2-channel NIRS may be a useful neuromarketing tool, since it allows objective assessment of pleasure-unpleasure. Keywords Prefrontal asymmetry TRS-NIRS Lipstick Comfort M. Tanida M. Okabe K. Tagai Shiseido Global Innovation Center, Yokohama, Japan K. Sakatani (*) NEWCAT Research Institute, Department of Electrical and Electronics Engineering, College of Engineering, 1 Nakagawara, Tokusada, Tamuramachi, Koriyama, Fukushima 963-8642, Japan Department of Neurological Surgery, School of Medicine, Nihon University, Tokyo, Japan e-mail: sakatani.kaoru@nihon-u.ac.jp Springer International Publishing AG 2017 H.J. Halpern et al. (eds.), Oxygen Transport to Tissue XXXIX, Advances in Experimental Medicine and Biology 977, DOI 10.1007/978-3-319-55231-6_29 215

216 M. Tanida et al. 1 Introduction Neuromarketing is a field of study that involves application of neuroscientific methods, such as neuroimaging techniques, to analyze and understand human behavior related to markets and marketing exchanges [1]. Magneto-encephalography (MEG), functional magnetic resonance imaging (fmri) and electroencephalography (EEG) have been used as neuroimaging techniques in neuromarketing research [2]. However, these techniques are not suitable for over-the-counter use. Near-infrared spectroscopy (NIRS) appears to be an attractive alternative method, since NIRS is compact and less stressful during measurements. Although 2-channel NIRS provides limited information about brain function, we can evaluate emotional responses based on the prefrontal cortex (PFC) activity measured by 2-channel NIRS [3 7]. In the present study, we investigate whether 2-channel NIRS allows us to objectively evaluate customer preferences for lipsticks. 2 Methods 2.1 Subjects We studied 14 women (aged 22.7 ± 1.6 years), all of whom were deemed righthanded according to the laterality quotient questionnaire of the Edinburgh Handedness Inventory. All subjects provided written informed consent as required by the Human Subjects Committee of the Shiseido Life Science Institute, Japan. 2.2 Experimental Protocol The subjects used two kinds of lipsticks (i.e. lipsticks A and B); lipstick A is softer than lipstick B, but there is no difference in color or flavor between them. We evaluated the feeling associated with use of the lipsticks using our original Visual Analog Scale (VAS) with four items, i.e., softness, comfort, liking, and melting texture; each item was scored from 0 to 100). In order to avoid possible effects of the VAS feeling evaluation on the PFC activity measured by NIRS, we evaluated the VAS after the NIRS measurement. In addition, the subject was not allowed to obtain any prior information about which lipstick they are using before the NIRS measurement. During the experiment, a photoelectric sensor (Tsuyama Mfg Co., Tokyo, Japan) was used to continuously monitor heart rate (HR). We employed quantitative, near-infrared time-resolved spectroscopy (TRS: Hamamatsu Photonics K.K, Hamamatsu, Japan) for measurement of the PFC activity evoked by the use of lipsticks A and B. Details of this system have been described previously [8 11]. Briefly, it consists of three pulsed laser diodes with different

29 Evaluation of Pleasure-Displeasure Induced by Use of Lipsticks 217 wavelengths (761, 791, and 836 nm) having a pulse duration of 100 ps at a repetition frequency of 5 MHz, a photomultiplier tube, and a circuit for time-resolved measurement based on the time-correlated single photon counting method. The observed temporal profiles were fitted to the photon diffusion TRSequation using the nonlinear least-squares fitting method. The reduced scattering and absorption coefficients for the three wavelengths were calculated. The concentrations of oxy-hb, deoxy-hb, and total Hb (=oxy-hb + deoxy-hb; t-hb) were then calculated using the least-squares method. The concentrations of Hb were expressed in μm. 2.3 Data Analysis The evoked CBO changes in the bilateral PFC were continuously monitored by TRS and were averaged every second during: (1) baseline conditions for 30 s; (2) use of lipstick A or B for 30 s; and (3) recovery for 30 s. To analyze PFC activity in response to the use of lipsticks, we calculated changes in oxy-hb concentration during lipstick use. The mean baseline values (measured during 30 s) were subtracted from the mean activation values (measured during the first 30 s of lipstick use). We evaluated the right and left dominancy of the PFC activity by calculating the Laterality Index (LI) (i.e., LI = leftδoxy-hb rightδoxy-hb); a positive LI indicates left-dominant activity while a negative LI indicates right-dominant activity.. 3 Results The VAS score of the melting texture for lipstick A was significantly higher than that for lipstick B (Fig. 29.1a). There was no significant difference in heart rate changes between lipstick A and B (Fig. 29.1b). Fig. 29.1 (a) Differences of VAS score between lipstick A (circles) and lipstick B (diamonds) (b) Changes of heart rate during the course of experiment (symbols as in (A))

218 M. Tanida et al. Fig. 29.2 Changes of oxy-hb in the right and left prefrontal cortex during use of lipsticks A and B TRS demonstrated different patterns of oxy-hb changes between lipsticks A and B (Fig. 29.2). That is, lipstick A induced an increase of oxy-hb in the left PFC associated with a decrease in the right PFC (LeftΔoxy-Hb = 0.15 ± 0.14, RightΔoxy-Hb = 0.22 ± 0.16), resulting in a left-dominant pattern. In contrast, lipstick B induced only small changes of oxy-hb (LeftΔoxy-Hb = 0.18 ± 0.35, RightΔoxy-Hb = 0.043 ± 0.30). We found a significant interaction between the use of lipsticks A and B, using a two-way factorial analysis of variance [F(1,13) = 9.63, p < 0.01]; Δoxy-Hb in the left PFC was larger than that in the right PFC during the use of lipstick A, while Δoxy-Hb in the right PFC tended to be larger than that in the left PFC during the use of lipstick B (p < 0.1) (Fig. 29.3a). In addition, the LI of lipstick A was larger than that of lipstick B (paired t-test, p = 0.0083) (Fig. 29.3b). 4 Discussion The present results indicate that use of lipstick A induced more left-dominant PFC activity than use of lipstick B. In addition, lipstick A showed a significantly higher score for melting texture than lipstick B. These findings are consistent with the valence-asymmetry hypothesis, which asserts that the left/right asymmetry of PFC activity is correlated with specific emotional responses to mental stress and personality traits [12 14]. More precisely, Davidson reported that the asymmetry of prefrontal electrical signals recorded from the surface of the scalp

29 Evaluation of Pleasure-Displeasure Induced by Use of Lipsticks 219 Fig. 29.3 (a) Changes of oxy-hb during use of lipsticks A and B in the right and left PFC (b) Laterality index of lipsticks A and B were related to emotional processes, insofar as there is relatively more left-frontal activity associated with positive emotion, whereas there is relatively more right-frontal activity associated with negative emotion [12]. This hypothesis has been confirmed in several studies using a variety of methods, including EEG, fmri, PET, and NIRS. In contrast to neuroimaging techniques such as fmri, PET, and multi-channel NIRS (so-called Optical Topography), 2-channel NIRS provides limited information about brain function. However, 2-channel NIRS allows us to evaluate positive and negative emotions induced by sensory stimulations based on the left/right asymmetry of PFC (i.e. the valence-asymmetry hypothesis). Thus, our present results indicate that 2-channel NIRS may be useful in neuromarketing, particularly in evaluation of customer preferences in the over-the-counter situation. Finally, it should be noted that we used time-resolved NIRS for measurements of PFC activity in the present study. In contrast to continuous-wave NIRS, timeresolved NIRS allows quantitative measurements of Hb concentration changes [8, 10, 11]. Thus, we could perform statistical analysis using the absolute values of Hb concentration changes induced by lipsticks A and B in the subjects, who might have had different values of optical pathlength [9]. Acknowledgments This research was supported in part by a Grant-in-Aid from the Ministry of Education, Culture, Sports, Sciences and Technology of Japan (Grant-in-Aid for Exploratory Research 25560356), and grants from Southern Tohoku Hospital (Fukushima, Japan) and Iing Co., Ltd. (Tokyo, Japan).

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